Display device employing light control member and display device manufacturing method

ABSTRACT

A liquid crystal is sealed with a sealing member between first and second transparent substrates, whereby a liquid crystal cell capable of transmitting ultraviolet light is produced. The liquid crystal cell is inserted into a mould into which an ultraviolet-setting resin is dropped and which is used to produce a light control member. The ultraviolet-setting resin is pressed to be bonded to the liquid crystal cell. In this state, ultraviolet light is irradiated to the liquid crystal cell in the mould from outside the mould. Thus, the ultraviolet-setting resin is set while bonding to the liquid crystal cell. Thereafter, the liquid crystal cell is removed from the mould. Consequently, the light control member is directly formed on the liquid crystal cell.

CROSS-REFERENCE TO RELATED APPLICATION

This application has priority over, and incorporates by reference, theentire disclosure of Japanese Patent Applications NOS. 2003-173335 and2003-17336 filed on Jun. 18, 2003.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a display device and a display devicemanufacturing method as well as a method of manufacturing the componentsof the display device. More particularly, the present invention isconcerned with a display device including an electro-optic convertingmember, which can control an amount of transmitted light by utilizing anelectric action, such as a liquid crystal cell, and also including alight control member for controlling refraction of light, a method ofmanufacturing the display device, and a method of manufacturing thecomponents of the display device.

2. Description of the Related Art

To date, liquid crystal display devices have rapidly been evolved as oneform of display device in various fields owing to the features of lowerpower consumption, thin design, low weight, and others. In particular,the liquid crystal display device is adopted for the majority ofpersonal digital assistant equipment, including portable cellularphones, whose prevalence has grown in recent years.

Moreover, the liquid crystal display device adopted for the personaldigital assistant equipment is designed with an emphasis on low powerconsumption for a longer service life of a battery. However, as theliquid crystal display device is not a type of display device that glowsitself, it is hard to discern the display in an environment in whichsufficient extraneous light is not available. Therefore, the personaldigital assistant equipment has a backlight disposed as an auxiliarylight source on one side of a liquid crystal cell opposite to the sideat which a viewer exists. The liquid crystal display device having thebacklight falls into a transmissive type and a transflective type.However, these types of liquid crystal display devices are very poor atefficient use of light.

A proposal has been made for a reflective liquid crystal display deviceincluding one polarizer and adopting a front light, which is disposed onthe side of a liquid crystal cell on which a viewer exists, as anauxiliary light source. However, as a light guide plate for introducinglight emitted from the front light is disposed on the side on which aviewer of the liquid crystal panel or cell lies, the liquid crystaldisplay device is made thicker by the thickness of the light guideplate. Normally, as the light guide plate has a thickness of about 1 mm,the liquid crystal display device becomes thicker by 1 mm at a minimum.Moreover, when the front light is adopted, a light guide plate havingunevenness is employed. Therefore, a protective plate called windshieldmust be placed on the external side of the light guide plate in order toprotect the light guide plate from damage. This increases the thicknessof the liquid crystal display device. In reality, when consideration istaken into the thickness of the windshield, an extra thickness of 3 mmis added to the thickness of the liquid crystal panel.

Japanese Unexamined Patent Application Publication No. 2001-33766 hasproposed a liquid crystal display device having an auxiliary lightsource mounted on a lateral side thereof. The liquid crystal displaydevice is of a reflective type having a reflecting layer formed on anoutermost layer thereof. The reflective liquid crystal display devicehas a liquid crystal layer sealed with a sealing member between twotransparent substrates. A first polarizing member supported using adouble-faced adhesive is placed on the external side of one of thetransparent substrates, and a light control member is disposed in aspace between the first polarizing member and the first transparentsubstrate. A second polarizing member is layered on the external side ofthe other transparent substrate, and a reflective layer is formed on theexternal side of the second polarizing member.

When incident light approximates a line perpendicular to the surface ofthe light control member, the light control member transmits the light.When the incident light approximates a line horizontal to the surfacethereof, the light control member reflects the light. The light controlmember is intended to increase an amount of light transmitted by theliquid crystal layer. A light source is in close contact with thelateral sides of the layered transparent substrates. The light controlmember reflects light, which emanates from the light source, in thedirection in which liquid crystalline molecules are aligned.

SUMMARY OF THE INVENTION

The foregoing light control member has an optical film bonded to the topof the first transparent substrate. If the light control member isdisplaced relative to the first transparent substrate, the adhesive viawhich the first polarizing member is supported on the first transparentsubstrate oozes out onto one end of the uneven portion of the lightcontrol member. This causes the first polarizing member to tilt relativeto the first transparent substrate. Consequently, the thickness of aliquid crystal display member increases. Furthermore, the same problemoccurs even when the adhesive is applied at an incorrect position on thelight control member. Moreover, even if the position of the lightcontrol member on the first transparent substrate is correct but theadhesive is applied at an incorrect position, the first polarizingmember tilts relative to the first transparent substrate for the samereason. Consequently, the thickness of a liquid crystal display memberincreases.

Furthermore, if the adhesive or the like is positioned on the lightcontrol member but not to the first transparent substrate, an object tobe bonded is changed from a predetermined one and a bond strength ischanged from a pre-set one. Besides, if the first polarizing membertilts, blurring of display occurs at a position away from the firsttransparent substrate. This results in an unclear display image.

An object of the present invention is to provide a display device thatincludes a light control member which is thin enough to be portable andthat can be manufactured at a low cost, a method of manufacturing thedisplay device, and a method of manufacturing the components of thedisplay device. Another object of the present invention is to provide adisplay device structured so that a first polarizing member placed on afirst transparent substrate will not tilt relative to the firsttransparent substrate even when a light control member is placed on thefirst transparent substrate.

The present invention is intended to accomplish the above objects andhas the first to twenty-second aspects described below.

According to the first aspect, there is provided a display devicecomprising: a first transparent substrate having an electrode; a secondtransparent substrate having an electrode; a display cell having anelectro-optic converting member, of which optical characteristic isvaried with an electric action, sealed between the first and secondtransparent substrates; and a light control member made of anultraviolet-setting resin and formed directly on the external side ofthe first transparent substrate opposite to the side thereof in contactwith the electro-optic converting member.

According to the second aspect, in the display device according to thefirst aspect, the electro-optic converting member is sealed between thesides of the first and second transparent substrates having therespective transparent electrodes formed thereon. The electro-opticconverting member can transmit ultraviolet light. The light controlmember is formed directly on the external side of the first transparentsubstrate, so that the ultraviolet light can be irradiated to the sideof the second transparent substrate opposite to the side thereof incontact with the electro-optic converting member.

According to the third aspect, the display device in accordance with thefirst aspect further comprises at least a light source mounted on theend surface of the first transparent substrate. The light control memberhas an irregular shape while having a plurality of parallel groovesformed along one of the edges of the first transparent substrate on theside thereof on which the light source is mounted.

According to the fourth aspect, the grooves formed in the display devicein accordance with the third aspect are V-shaped grooves.

According to the fifth aspect, in the display device according to thefirst aspect, the maximum height of the portion of the light controlmember near the light source is smaller than the height of the portionthereof away from the light source.

According to the sixth aspect, in the display device according to thefirst aspect, a first polarizing member supported by a spacer is placedon the external side of the light control member opposite to the sidethereof in contact with the first transparent substrate. The surface ofthe spacer on which the first polarizing member is supported is locatedhigher than the light control member.

According to the seventh aspect, in the display device according to thesixth aspect, the spacer formed around a display area of the displaydevice is made of the same material as the light control member.

According to the eighth aspect, in the display device according to thefirst aspect, the light control member formed on the external side ofthe first transparent substrate lies over the entire surface of thefirst transparent substrate.

According to the ninth aspect, in the display device according to thesixth aspect, the spacer is an adhering member mounted on the irregularportion of the light control member.

According to the tenth aspect, in the display device according to thesixth aspect, the spacer is formed at least along one edge of a framearea around a display area of the display device.

According to the eleventh aspect, in the display device according to thetenth aspect, the one edge is one of the edges of the area around thedisplay area that is located farthest away from the light source.

According to the twelfth aspect, in the display device according to thefirst aspect, the first transparent substrate has a portion thereofjutting out relative to the second transparent substrate. The lightcontrol member formed on the external side of the first transparentsubstrate lies over the entire surface thereof except the jut portion.

According to the thirteenth aspect, there is provided a method ofmanufacturing the display device in accordance with the first aspect.The display device manufacturing method comprises the steps of:producing a display cell that can transmit ultraviolet light; pouring anultraviolet-setting resin into a mould that is engraved along with theshape of the light control member; placing the display cell on theultraviolet-setting resin in the mould so that the display cell will besuperposed on the ultraviolet-setting resin; irradiating ultravioletlight to the side of the display cell opposite to the side thereof incontact with the ultraviolet-setting resin; allowing theultraviolet-setting resin to set with the ultraviolet light transmittedby the display cell; and removing the display cell from the mould so asto thus form the light control member on the display cell.

According to the fourteenth aspect, in the display device according tothe first aspect, the display cell has a liquid crystal sealed betweenthe first and second transparent substrates. A sealing member is used toprevent the liquid crystal from leaking out of a gap between the firstand second transparent substrates.

According to the fifteenth aspect, in the display device manufacturingmethod according to the thirteenth aspect, the display cell put in themould is a single display cell.

According to the sixteenth aspect, in the display device manufacturingmethod according to the thirteenth aspect, the display cell put in themould is a set of a plurality of display cells.

According to the seventeenth aspect, the display device manufacturingmethod according to the fifteenth aspect further comprises a step ofcutting the set of display cells apart so as to produce a single displaycell.

According to the eighteenth aspect, there is provided a method ofmanufacturing the display device in accordance with the first aspect.The display device manufacturing method comprises the steps of:producing at least an electrode on a first transparent substrate;pouring an ultraviolet-setting resin in a mould that is engraved alongwith the shape of a light control member; putting the first transparentsubstrate, which has the electrode formed thereon, on theultraviolet-setting resin in the mould so that the first transparentsubstrate will be superposed on the ultraviolet-setting resin;irradiating ultraviolet light to the side of the first transparentsubstrate opposite to the side thereof in contact with theultraviolet-setting resin; allowing the ultraviolet-setting resin to setwith the ultraviolet light transmitted by the first transparentsubstrate; removing the first transparent substrate from the mould so asto thus form the light control member on the first transparentsubstrate; bonding the first transparent substrate to a secondtransparent substrate; and sandwiching an electro-optic convertingmember between the first and second transparent substrates.

According to the nineteenth aspect, in the display device manufacturingmethod according to the eighteenth aspect, the electrode formed on thefirst transparent substrate is coated with an alignment layer.

According to the twentieth aspect, in the display device manufacturingmethod according to the eighteenth aspect, the first transparentsubstrate having the electrode created thereon and being put in themould is a sole first transparent substrate.

According to the twenty-first aspect, in the display devicemanufacturing method according to the eighteenth aspect, the firsttransparent substrate having the electrode formed thereon and being putin the mould is a set of a plurality of first transparent substrates.

According to the twenty-second aspect, the display device manufacturingmethod according to the twenty-first aspect further comprises a step ofcutting the set of first transparent substrates apart so as to produce asingle first transparent substrate.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be more clearly understood from thedescription set forth below with reference to the accompanying drawings,wherein:

FIG. 1A is a sectional view of the structure of an example of aconventional liquid crystal display device having a light source mountedon a lateral side thereof;

FIG. 1B is a sectional view showing the structure of another example ofa conventional liquid crystal display device having a light sourcemounted on a lateral side thereof;

FIG. 2 is a perspective view showing the structure of an optical filmemployed in FIG. 1A and FIG. 1B;

FIG. 3 is an explanatory diagram concerning a problem which arises whenthe optical film is not attached to a correct position in the liquidcrystal display device shown in FIG. 1A;

FIG. 4A is a sectional view showing the structure of a liquid crystaldisplay device including a first example of a liquid crystal cellemployed in the present invention;

FIG. 4B is a sectional view showing the structure of a liquid crystaldisplay device including a second example of a liquid crystal cellemployed in the present invention;

FIG. 5A is a sectional view showing the structure of a variant of theliquid crystal display device including the first example of a liquidcrystal cell employed in the present invention;

FIG. 5B is a sectional view showing the structure of a variant of theliquid crystal display device including the second example of a liquidcrystal cell employed in the present invention;

FIG. 6A is a sectional view showing the structure of a liquid crystaldisplay device including a third example of a liquid crystal cellemployed in the present invention;

FIG. 6B is a sectional view showing the structure of a liquid crystaldisplay device including a fourth example of a liquid crystal cellemployed in the present invention;

FIG. 7A to FIG. 7E show steps constituting an example of a method ofmanufacturing the liquid crystal cell employed in the present invention;

FIG. 8A is a sectional view showing one of steps constituting anotherexample of a method of manufacturing the liquid crystal cell employed inthe present invention;

FIG. 8B is a side view of a liquid crystal cell having a light controlmember and being produced at the manufacturing step shown in FIG. 8A;

FIG. 8C is a perspective view showing the appearances of the liquidcrystal cell produced at the step shown in FIG. 8A and of a mouldemployed at the step;

FIG. 9A is a sectional view showing one of steps constituting anotherexample of a method of manufacturing the liquid crystal cell employed inthe present invention;

FIG. 9B is a side view of a liquid crystal cell having a light controlmember and being produced at the manufacturing step shown in FIG. 9A;

FIG. 10 is a perspective view showing the appearances of liquid crystalcells produced according to another method of manufacturing the liquidcell employed in the present invention and the appearance of a mouldemployed in the method;

FIG. 11A is a perspective view showing the appearances of liquid crystalcells produced according to another method of manufacturing the liquidcell employed in the present invention and the appearance of a mouldemployed in the method;

FIG. 11B is a perspective view showing a state in which the liquidcrystal cells shown in FIG. 11A are placed on the mould shown therein;

FIG. 12A is a sectional view showing the structure of a liquid crystaldisplay device including a fifth example of a liquid crystal cellemployed in the present invention;

FIG. 12B is a sectional view showing one of steps constituting a methodof manufacturing a liquid crystal cell included in the liquid crystaldisplay device shown in FIG. 12A;

FIG. 13A is a plan view of a liquid crystal display device not having alight control member formed on an extended portion of a firsttransparent substrate;

FIG. 13B is a plan view of a liquid crystal display device having alight control member formed on an extended portion of a firsttransparent substrate;

FIG. 14A is a plan view of a liquid crystal display device showing anexample in which a double-faced adhesive, an adhering member, or aspacer that supports a first polarizing member included in the presentinvention is formed on a liquid crystal cell as if to be a frame havingfour edges;

FIG. 14B is a plan view of a liquid crystal display device showing anexample in which a double-faced adhesive, an adhering member, or aspacer that supports the first polarizing member included in the presentinvention is formed on a liquid crystal cell as if to be a frame havingthree edges;

FIG. 14C is a plan view of a liquid crystal display device showing anexample in which a double-faced adhesive, an adhering member, or aspacer that supports the first polarizing member included in the presentinvention is formed on a liquid crystal cell as if to be a frame havingtwo edges;

FIG. 15A is a plan view of a liquid crystal display device showing anexample in which a double-faced adhesive, an adhering member, or aspacer that supports the first polarizing member included in the presentinvention is formed on a liquid crystal cell along an edge of the liquidcrystal cell opposite to an edge thereof on which a light source ismounted;

FIG. 15B is a sectional view of the liquid crystal display device shownin FIG. 15A;

FIG. 16A to FIG. 16E show steps constituting an example of a method ofmanufacturing a transparent substrate, which is one of the components ofa display device in accordance with the present invention, having anelectrode formed thereon;

FIG. 17A is a sectional view showing a first embodiment of a liquidcrystal display device which is manufactured using the component thathas a light control member and is produced according to themanufacturing method shown in FIG. 16A to FIG. 16E, and which includes areflective layer in a liquid crystal cell thereof;

FIG. 17B is a sectional view showing a second embodiment of a liquidcrystal display device which is manufactured using the component thathas a light control member and is produced according to themanufacturing method shown in FIG. 16A to FIG. 16E, and which includes areflective layer in a liquid crystal cell thereof;

FIG. 17C is a sectional view showing a third embodiment of a liquidcrystal display device which is manufactured using the component thathas a light control member and is produced according to themanufacturing method shown in FIG. 16A to FIG. 16E, and which includes areflective layer in a liquid crystal cell thereof; and

FIG. 17D is a sectional view showing a fourth embodiment of a liquidcrystal display device which is manufactured using the component thathas a light control member and is produced according to themanufacturing method shown in FIG. 16A to FIG. 16E, and which includes areflective layer in a liquid crystal cell thereof.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Prior to a description of the preferred embodiments of the presentinvention, a liquid crystal display device employing a conventionallight control member and a method of manufacturing the display devicewill be described in conjunction with FIG. 1A to FIG. 2.

FIG. 1A shows a liquid crystal display device 1 described in JapaneseUnexamined Patent Application Publication No. 2001-33766. The liquidcrystal display device 1 is of a reflective type having a reflectivelayer 27 formed as an outermost layer of the liquid crystal displaydevice 1. The liquid crystal display device 1 has a liquid crystal layer26 sealed with a sealing member 24 between a first transparent substrate16 and a second transparent substrate 19. The thickness of the liquidcrystal layer 26 is about 5 μm. A first polarizing member 10 composed ofa first polarizer 12 and a phase difference plate 14 is placed on theexternal side of the first transparent substrate 16 while beingsupported by a spacer 21. A supporting member having an adhesive appliedto both ends of a base member may be substituted for the spacer 21. Alight control member 120 is formed in a space 3 between the firstpolarizing member 10 supported by the spacer 21 and the firsttransparent substrate 16. A second polarizer 108 is layered on theexternal side of the second transparent substrate 19, and the reflectivelayer 27 is formed on the external side of the second polarizer 108.

The light control member 120 is formed by bonding a film, of which thethickness is about 100 μm, to the top of the first transparent substrate16 directly or with an adhesive between them. The light control member120 has unevenness extended in a direction perpendicular to an edge ofthe display device on which a light source 122 is mounted. The unevenportion extends parallel to the edge of the display device on which thelight source 122 is mounted, and is realized with a plurality ofequidistant grooves so that any part of the uneven portion will have thesame cross-sectional shape (triangularly projecting shape). Moreover,the cross section of the uneven portion is characterized by a segmentthat has an angle of elevation of 4.6° relative to a horizontal planeparallel to the top of the light source 122 and has a length of 45 μm,and a segment that has an angle of depression of 20° relative to ahorizontal plane containing the terminal point of the segment and has alength of 55 μm. The height of a ridge defined by the two segments is 20μm. The light control member 120 has the ridge repeatedly formed with apitch of 0.3 mm between adjoining ridges.

When incident light approximates a line perpendicular to the surface ofthe light control member 120 having the foregoing structure, the lightcontrol member 120 transmits the light. When the incident lightapproximates a line horizontal thereto, the light control memberreflects the light.

The light source 122 is brought into close contact with the lateralsides of the first and second transparent substrates 16 and 19respectively. Among light rays emitted from the light source 122, alight ray 126 heading for the reflective layer 27 is reflected from thereflective layer 27, and radiated to the outside by way of the lightcontrol member 120. Moreover, a light ray 124 emitted from the lightsource 122 and heading for the light control member 120 is reflectedfrom the light control member 120 to the liquid crystal layer 26, andreflected again from the reflective layer 27. Thereafter, the light rayis radiated to outside by way of the light control member 120. Moreover,light 128 coming from outside passes through the light control member120, and is reflected from the reflective layer 27 and radiated tooutside.

FIG. 1B shows the structure of a conventional scattering liquid crystaldisplay device 2. The same reference numerals are assigned to componentsidentical to those of the reflective liquid crystal display device 1shown in FIG. 1A. The liquid crystal display device 2 shown in FIG. 1Bhas, similarly to the liquid crystal display device 1 shown in FIG. 1A,a liquid crystal layer 26 sealed with a sealing member 24 between afirst transparent substrate 16 and a second transparent substrate 19.The only difference from the reflective liquid crystal display device 1is that a liquid crystal adopted as the liquid crystal layer 26 is of ascattering type that permits control of scattering and transmission oflight with application of a voltage.

Unlike the liquid crystal display device 1, a first polarizing member 10composed of a first polarizer 12 and a phase difference plate 14 is notplaced on the external side of the first transparent substrate 16.However, a light control member 120 similar to the one included in theliquid crystal display device 1 is formed on the first transparentsubstrate 16.

A light source 122 is mounted on the lateral sides of the first andsecond transparent substrates 16 and 19 respectively. Among light raysemitted from the light source 122, a light ray heading for the lightcontrol member 120 is reflected from the light control member, andradiated to outside (downward in FIG. 1B) by way of the firsttransparent substrate 16, liquid crystal layer 26, and secondtransparent substrate 19. Moreover, among the light rays emitted fromthe light source 122, a light ray getting out of the second transparentsubstrate 19 is reflected from the second transparent substrate, headedfor the light control member 120, reflected from the light controlmember, and radiated to outside (downward in FIG. 1B) by way of thefirst transparent substrate 16, liquid crystal layer 26, and secondtransparent substrate 19.

FIG. 2 shows an example of a light control member 120 disclosed inJapanese Unexamined Patent Application Publication No. 2001-83304. Thelight control member 120 is realized with an optical film having anuneven portion 150 formed on an even portion 152. In terms of filmstrength, the even portion 152 must have a thickness of at least severaltens of micrometers.

When the optical film described in Japanese Unexamined PatentApplication Publication No. 2001-833304 is employed in the liquidcrystal display device 1 shown in FIG. 1A, the thickness of the liquidcrystal display device 1 increases. Moreover, as the optical film isbonded in an early stage of a process of manufacturing a liquid crystaldisplay device, the optical film must have durability to chemicals usedat succeeding steps and durability to heat applied at succeeding steps.An optically preferable material has not been found.

FIG. 1A and FIG. 1B show cases where the optical film 120 is placed inposition on the first transparent substrate 16. As shown in FIG. 3,showing the same structure as the one of FIG. 1A, the optical film 120need not be placed in position on the first transparent substrate 16 butmay be, for example, displaced rightward in the drawing. In this case,the spacer 21 is mounted on the light control member 120. Consequently,the first polarizing member 10 is not parallel to the first transparentsubstrate 16. Eventually, the thickness of the liquid crystal displaydevice 1 increases, and an object to be bonded with the spacer 21changes to vary a bond strength.

Moreover, even when the optical film 120 is placed in position on thefirst transparent substrate 16, if part or the whole of the spacer 21 ismounted on the optical film 120 and bonded thereto, the first polarizingmember 10 tilts relative to the first transparent substrate 16.Furthermore, when the first polarizing member 10 tilts, a blur ofdisplay occurs at a position away from the first transparent substrate16. This poses a problem in that a display image becomes unclear.

The present invention attempts to solve the problems underlying theconventional liquid crystal display devices. A description will be madeof a liquid crystal display device in accordance with the presentinvention including a thin light control member and realizing a lowercost of manufacture, and a method of manufacturing the display device.In descriptions of embodiments of the present invention, for a betterunderstanding, the same reference numerals will be assigned tocomponents identical to those of the conventional liquid crystal displaydevices 1 and 2 described in conjunction with FIG. 1A to FIG. 3.

FIG. 4A shows the structure of a liquid crystal display device 1Aincluding a first example of a liquid crystal cell employed in thepresent invention. The liquid crystal display device 1A has a liquidcrystal layer 26 sealed with a sealing member 24 between a firsttransparent substrate 16 and a second transparent substrate 19. Thethickness of the liquid crystal layer 26 is about 5 μm. A firstpolarizing member 10 composed of a first polarizer 12 and a phasedifference plate 14 is placed on the external side of the firsttransparent substrate 16 while being supported by a spacer 21. A lightcontrol member 120 is formed in a space 3 between the first polarizingmember 10 supported by the spacer 21 and the first transparent substrate16. A second polarizer 108 is layered on the external side of the secondtransparent substrate 19. A reflective layer 27 is formed on theexternal side of the second polarizer 108. A transparent electrode andan alignment layer are formed on the sides of the first and secondtransparent substrates 16 and 19 clamping the liquid crystal layer 26,though they are not shown. A light source 122 is mounted on one lateralsides of the first and second transparent substrates 16 and 19, andrealized with LEDs or a fluorescent tube.

The light control member 120 employed in this example is made of anultraviolet-setting resin and is formed directly on the firsttransparent substrate 16. The side of the light control member 120opposite to the side thereof in contact with the first transparentsubstrate 16 has unevenness, and the uneven portion is realized byforming a plurality of V-shaped grooves equidistantly. The grooves arejuxtaposed in parallel to an edge of the liquid crystal cell on whichthe light source 122 is mounted. Moreover, the uneven portion ischaracterized by a segment whose angle of elevation relative to ahorizontal plane parallel to the top of the light source 122 is 4.6° andwhose length is 245 μm and a segment whose angle of depression relativeto a horizontal plane containing a limit of the segment is 20° and whoselength is 55 μm. The height of a ridge defined with the two segments is20 μm. The light control member 120 has the ridge repeatedly formed witha pitch of 0.3 mm between adjoining ridges. Noted is that thesenumerical values are presented as examples. The angles and shapedefining the ridge vary depending on the size of a liquid crystal panelor the number of pixels.

When incident light approximates a line perpendicular to the surface ofthe light control member 120 having the foregoing structure, the lightcontrol member 120 transmits the light. When the incident lightapproximates a line horizontal thereto, the light control member 120reflects the light. Transmission or reflection of light by the lightcontrol member 120 has been described in conjunction with FIG. 1A. Thereiteration will be omitted. Moreover, a procedure of forming the lightcontrol member on the first transparent substance 16 will be describedlater. The spacer 21 in this example is formed with an adhering memberexhibiting adhesion to each of the first polarizing member 10 and firsttransparent substrate 16. The adhering member may be formed with anadhesive alone or by applying an adhesive to both ends of a base memberof the adhering member.

The upper side in the drawing of the liquid crystal display device 1Ahaving the first example is a viewer side. The first transparentsubstrate 16 is extended in the direction of an edge of the liquidcrystal cell opposite to the edge thereof on which the light source 122is mounted, and gets longer than the second transparent substrate 19. Anintegrated circuit 36 for driving the liquid crystal display device 1Ais attached to the bottom of the extended portion with an anisotropicconductive film 38 containing conductive particles 40 between them.

FIG. 4B shows the structure of a liquid crystal display device 1Bincluding a second example of a liquid crystal cell employed in thepresent invention. The liquid crystal display device 1B is differentfrom the liquid crystal display device 1A in the shape of the lightcontrol member 120. In the liquid crystal display device 1A, thecontinuous triangular cross-sectional shape of the light control member120 is the same between one portion of the light control member 120located near the light source 122 and the other portion thereof locatednear the integrated circuit 36. On the other hand, in the liquid crystaldisplay device 1B, the continuous triangular cross-sectional shape ofthe portion of the light control member 120 located near the lightsource 122 is smaller and the continuous triangular cross-sectionalshape of the portion thereof located near the integrated circuit 36 islarger. In other words, the height of the continuous triangularcross-sectional shape of the portion of the light control member 120located near the integrated circuit 36 is larger than the height of thecontinuous triangular cross-sectional shape of the portion thereoflocated near the light source 122. Incidentally, neither transparentelectrodes nor alignment layers are shown in FIG. 4B.

The height of the triangular cross-sectional shape is determined so thatit will become gradually larger as it recedes from the light source 122to approach the integrated circuit 36. This is because light emittedfrom the light source 122 gets weaker as it recedes from the lightsource 122 and is the weakest at the integrated circuit 36. As theportion of the light control member 120 having a larger triangularcross-sectional area exhibits a higher index of refraction than theportion thereof having a smaller cross-sectional area, the portion ofthe light control member 120 having the larger triangularcross-sectional area reflects a larger amount of light. Although lightemitted from the light source 122 gets weakened at the integratedcircuit 36, as the light control circuit 120 reflects a larger amount oflight, the luminance on the display surface of a liquid crystal cell 54given by light emitted from the light source 122 mounted on one edge ofthe first transparent substrate 16 is equalized.

The light control member 120 having the shape shown in FIG. 4B can bereadily manufactured by engraving the shape of the light control member120 in a mould in advance. In the light control member 120 shown in FIG.4A, the triangular cross-sectional shape is high all over the surface ofthe light control member 120. Depending on a required opticalcharacteristic, part of the triangular cross-sectional shape may be highor the triangular cross-sectional shape may get gradually higher. Theheight of the triangular cross-sectional shape may not only be variedlinearly but may be varied as if to plot a graph of a square functionwith a certain curvature. Moreover, for a larger amount of reflectedlight, the height of the triangular cross-sectional shape may beincreased or the density of triangular cross-sectional shapes may beraised.

FIG. 5A shows the structure of a variant of the liquid crystal displaydevice 1A including the first example of a liquid crystal cell employedin the present invention. The liquid crystal display device 1A shown inFIG. 5A is different from the liquid crystal display device 1A shown inFIG. 4A in the spacer 21 supporting the first polarizing member 10. Thespacer 21 is made of a base member 60 having a predetermined height, andthe top and bottom of the base member 60 are bonded to the firsttransparent substrate 16 and first polarizing member 10 respectivelyusing an adhesive 62. Incidentally, neither transparent electrodes noralignment layers are shown in FIG. 5A.

FIG. 5B shows the structure of a variant of the liquid crystal displaydevice 2B including the second example of a liquid crystal cell employedin the present invention. The liquid crystal display device 1B shown inFIG. 5B is different from the liquid crystal display device 1B shown inFIG. 4B in a point that the spacer 21 supporting the first polarizingmember 10 is replaced with an adhering member 22 having the samestructure as the one shown in FIG. 5A. Incidentally, neither transparentelectrodes nor alignment layers are shown in FIG. 5B.

As mentioned above, when the adhering member 22 including the basemember 60 is used to support the first polarizing member 10, since theheight of the base member 60 is constant, a predetermined space 3 can bepreserved between the first polarizing member 10 and the firsttransparent substrate 16.

FIG. 6A shows the structure of a liquid crystal display device 1Cincluding a third example of a liquid crystal cell employed in thepresent invention. The liquid crystal display device 1C shown in FIG. 6Ais different from the liquid crystal display device 1A shown in FIG. 4Ain the deposition of the light control member 120 on the firsttransparent substrate 16. In the liquid crystal display device 1A shownin FIG. 4A, the light control member 120 is formed inside thedouble-faced adhesive 120. In contrast, in the liquid crystal displaydevice 1C including the third example as shown in FIG. 6A, the lightcontrol member 120 is extended to a portion of the first transparentsubstrate 16 indicated with 120F. Incidentally, neither transparentelectrodes nor alignment layers are shown in FIG. 6A.

The spacer 21 is therefore mounted on the extended portion 120F of thelight control member 120, and adheres to each of the light controlmember 120 and first polarizing member 10. When the light control member120 has the extended portion 120F, the spacer 21 is bonded to the lightcontrol member 120. In the case of the liquid crystal display device 1Ashown in FIG. 4A, the spacer 21 must be accurately bonded to the lightcontrol member 120 for fear the spacer may be superposed on the lightcontrol member 120. In this example of a liquid crystal cell, since thespacer 21 is bonded to the light control member 120, the light controlmember 120 need not be accurately formed on the first transparentsubstrate 16. The spacer 21 included in this example is realized with anadhering member having enough adhesion to each of the first polarizingmember 10 and light control member 120. The adhering member may berealized with an adhesive alone or with a base member having an adhesiveapplied to both ends thereof.

FIG. 6B shows the structure of a liquid crystal display device 1Dincluding a liquid crystal cell employed in the present invention. Theliquid crystal display device 1D shown in FIG. 6B is different from theliquid crystal display device 1C shown in FIG. 6A in a position at whichthe light control member 120 is formed. In the liquid crystal displaydevice 1D shown in FIG. 6B, the light control member 120 is extended tothe portion of the first transparent substrate 16 having the integratedcircuit 36 attached thereto. Even in the present example of a liquidcrystal cell, the spacer 21 need not be accurately bonded to the firsttransparent substrate 16. Incidentally, neither transparent electrodesnor alignment layers are shown in FIG. 6B.

FIG. 7A to FIG. 7E show steps constituting an example of a method ofmanufacturing a liquid crystal cell employed in the present invention.

FIG. 7A shows a state in which an appropriate quantity of anoptical-setting resin 52 is dropped into a mould 50. The mould 50 hasV-shaped grooves 51, which correspond to the uneven portion of the lightcontrol member 120, formed in the bottom thereof. The V-shaped grooves51 are formed equidistantly in the bottom of the mould 50. Thecontinuous triangular cross-sectional shape of the V-shaped grooves 51may be a right angled triangle, an isosceles triangle, or a scalenetriangle. Moreover, as the optical-setting resin 52, for example, anacrylic ultraviolet-setting adhering resin may be adopted.

Concurrently with, or prior to, the step of dropping an appropriatequantity of the optical-setting resin 52 into the mould 50, the liquidcrystal cell 54 is prepared by superposing the first and secondtransparent substrates 16 and 19 on each other and then sealing theliquid crystal layer 26 with the frame-like sealing member 24 betweenthe first and second transparent substrates. Neither transparentelectrodes nor alignment layers are shown in FIG. 7A. The liquid crystalcell 54 is, as shown in FIG. 7B, inserted into the mould 50 with thefirst transparent substrate 16 opposed to the mould 50, and thenpressed. At this time, the resin 52 in the mould 50 spreads all over themould 50 while being pressed by the first transparent substrate 16, andenters all the grooves 51. The quantity of the resin 52 is preferablyequal to the total volume of the grooves 51 in the mould 50. However, asthe grooves 51 must be filled with the resin 52, the quantity of theresin 52 is larger than the volume of the grooves 51. The mould 50 hasan escape groove (not shown), into which the resin 52 is led, formed sothat an excessive quantity of the resin 52 leaking out of the grooves 51can be removed.

FIG. 7C shows a state in which the grooves in the mould 50 are fullyfilled with the resin 52 while being in contact with the firsttransparent substrate 16. In this example of a liquid crystal cell, inthis state, a light source 58 that emits ultraviolet light and islocated outside the liquid crystal cell 54 is used to irradiateultraviolet light to the second transparent substrate 19 included in theliquid crystal cell 54. At this time, the liquid crystal cell 54including the liquid crystal layer is transparent to ultraviolet light.Therefore, the ultraviolet light is transmitted by the liquid crystalcell 54 and irradiated onto the resin 52. Consequently, the resin 52 isset by the ultraviolet light while adhering to the first transparentsubstrate 16.

After the resin 52 sets while adhering to the first transparentsubstrate 16, when the liquid crystal cell 54 is, as shown in FIG. 7D,peeled off from the mould 50, the resin 52 is transferred as the lightcontrol member 120 to the liquid crystal cell 54. FIG. 7E shows theliquid crystal cell 54 having the light control member 120 thus formedthereon. The liquid crystal cell 54 formed according to the foregoingmanufacturing method can be adapted to the liquid crystal display device1D described in conjunction with FIG. 6B.

As mentioned above, the light control member 120 formed on the firsttransparent substrate 16 does not require an even portion correspondingto the even portion 152 of the optical film shown in FIG. 2. Therefore,the light control member 120 can be formed thinly. This helps realize athin liquid crystal display device.

The liquid crystal cell 54 employed in the foregoing manufacturingmethod may be a finished goods having a liquid crystal substance sealedtherein or a semifinished goods having the sealing member 24 formedtherein but not having the liquid crystal substance sealed therein.Moreover, the resin 52 may be a thermosetting resin. In this case, thelight control member 120 is preferably formed on a semifinished liquidcrystal cell, in which a liquid crystal substance is not sealed, inorder to prevent deterioration of the quality of the liquid crystalsubstance.

When the light control member 120 is formed using a mould in the samemanner as it is in this example, if the number of manufactured productsin one mould is large, the cost of manufacture becomes very low.Furthermore, as long as the mould is produced highly precisely, it iseasy to align the mould 50 with the liquid crystal cell 54. Moreover, asthe light control member 120 is formed on the liquid crystal cell 54having the first and second transparent substrates 16 and 19 bonded toeach other using the sealing member 24, the number of manufacturingsteps succeeding formation of the light control member is small, and therisk that the uneven portion of the light control member 120 is flawedis reduced. After the light control member 120 is formed on a firsttransparent substrate using the mould 50, the liquid crystal cell 54 maybe completed using the first transparent substrate.

Moreover, at the step when the light control member 120 is formed on theliquid crystal cell 54 that is made by using the sealing member 24,almost all steps of manufacturing the liquid crystal cell 54 havefinished. So that the number of remaining steps for manufacturing aliquid crystal cell is small, the number of chemicals to be used at thesucceeding steps is small, and the number of succeeding steps at whichhigh temperature processing is performed is small. Consequently, a resinthat is to be made into the light control member 120 and has durabilityto the chemicals and durability to high temperature can be selectedeasily, and a resin exhibiting a good optical characteristic can beselected.

FIG. 8A is a sectional view showing one of steps constituting anotherexample of a method of manufacturing a display device in accordance withthe present invention. The step corresponds to the step included in theaforesaid manufacturing method and shown in FIG. 7B. In this example,the bottom of the mould 50 has even sections 53 in addition to thegrooves 51. The even sections 53 are, as shown in FIG. 8C, formed inparallel with the grooves 51 along two edges of the bottom of the mould50. The even sections 53 may be formed along any edges of the bottom ofthe mould 50, and the number of even sections 53 is not limited to anyvalue.

FIG. 8B shows the light control member 120 formed on the liquid crystalcell 54 at the manufacturing step shown in FIG. 8A. Owing to the evensections 53 formed in the bottom of the mould 50, the liquid crystalcell 54 has portions that are devoid of the light control member 120.The liquid crystal cell 54 manufactured according to this manufacturingmethod can be adapted to the liquid crystal display device 1A that hasspaces by the sides of the light control member 120 as shown in FIG. 4Aand FIG. 5A.

FIG. 9A is a sectional view showing one of steps constituting anotherexample of a method of manufacturing a display device in accordance withthe present invention. The step corresponds to the step included in theaforesaid manufacturing method and shown in FIG. 7B. In this example,even sections 53 are formed along two edges of the bottom of the mould50. Moreover, a groove adjoining one of the even sections 53 is ashallow groove 51S, and a groove adjoining the other even section 53 isa deep groove 51D. Namely, the grooves 51 get gradually deeper from thegroove 51S to the groove 51D.

FIG. 9B shows the light control member 120 formed on the liquid crystalcell 54 at the manufacturing step shown in FIG. 9A. Owing to the evensections 53 formed in the mould 50, the liquid crystal cell 54 hasportions having no light control member 120. Moreover, the height of thelight control member 120 varies from a height L1 to a height L2 (>L1).The liquid crystal cell 54 produced according to this manufacturingmethod is adapted to the liquid crystal display device 1B shown in FIG.4B and FIG. 5B.

FIG. 10 is a perspective view showing the appearances of liquid crystalcells produced according to another method of manufacturing a displaydevice in accordance with the present invention and the appearance of amould employed therein. In this example, a light control member isformed on a set 55 of liquid crystal cells including a plurality ofliquid crystal cells 54 each having a liquid crystal sandwiched betweena first transparent substrate and a second transparent substrate. Inthis example, the set 55 of liquid crystal cells having the rectangleliquid crystal cells 54 arranged tandem (a set of four liquid crystalcells 54) is put in a large mould 50P that has the grooves 51 and evensections 53 and that is designed to produce a plurality of light controlmembers. The light control member 120 can therefore be simultaneouslyformed on the four liquid crystal cells 54 arranged tandem. After thelight control member 120 is formed, the respective liquid crystal cells54 are cut apart. When this method is adopted, the liquid crystal cell54 may be either a finished panel having a liquid crystal substancesealed therein or a semifinished liquid crystal cell not having a liquidcrystal sealed therein.

FIG. 11A is a perspective view showing the appearances of liquid crystalcells produced according to still another method of manufacturing adisplay device in accordance with the present invention and theappearance of a mould employed therein. FIG. 11B is a perspective viewshowing a state in which liquid crystal cells are put in the mould shownin FIG. 11A. In this example, a common mould 50C whose opening is largerthan the set 55 of liquid crystal cells 54 is prepared. The set 55 ofliquid crystal cells 54 is, as shown in FIG. 11B, put in part of thelarge common mould 50C, and supported using a jig that is not shown. Thecommon mould 50C can be used in common for liquid crystal cells havingdifferent sizes. This obviates the necessity of preparing a plurality ofmoulds according to the sizes of liquid crystal cells 54, and is highlyeconomic.

FIG. 12A is a sectional view showing the structure of a liquid crystaldisplay device 1E including a fifth example of a liquid crystal cellemployed in the present invention. In this example, a spacer 70 higherthan the uneven portion of the light control member and made of the samematerial as the light control member 120 is formed along the edges ofthe light control member 120 formed on the first transparent substance16. The spacer 70 is bonded to the first polarizing member 10 with anadhesive 62 applied to the top thereof. The other components of theliquid crystal display device 1E are identical to those of the liquidcrystal display device 1A shown in FIG. 4A. Neither transparentelectrodes nor alignment layers are shown in FIG. 12A.

A spacer groove 56 is, as shown in FIG. 12B, formed along the edges ofthe mould 50, whereby the spacer 70 is formed concurrently with thelight control member 120 during formation of the light control member120. Consequently, unlike the aforesaid example, the spacer 21 forkeeping the light control member 120 and first polarizing member 10apart from each other and the adhering member 20 including the basemember 60 are unnecessary. Accordingly, only by applying the adhesive 62to the spacer 70, the spacer 70 can be bonded to the first polarizingmember 10.

In the structure shown in FIG. 12A and FIG. 12B, the spacer 70 can beformed concurrently with the light control member 120 during formationof the light control member 120. Furthermore, as the height of thespacer 70 is uniform all the time, it is easy to bond the spacer 70 tothe first polarizing member 10. Moreover, once the shape of the spaceris engraved in the mould 50 in advance, the spacer 70 can be formedwithout an increase in cost.

FIG. 13A is a plan view of the liquid crystal display device 1C shown inFIG. 6A, and FIG. 13B is a plan view of the liquid crystal displaydevice 1D shown in FIG. 61. In the liquid crystal display device 1Cshown in FIG. 13A, the extended portion of the first transparentsubstrate 16 is devoid of the light control member 120. In contrast, inthe liquid crystal display device 1D shown in FIG. 13B, the extendedportion 16A of the first transparent substrate 16 has the light controlmember 120.

FIG. 14A shows an example in which the spacer 21, adhering member 22, orspacer 70 that supports the first polarizing member 10 employed in thepresent invention is formed like a frame having four edges on the liquidcrystal cell 54. A field indicated with a dot-dash line is a displayarea 74 on a liquid crystal display device. FIG. 14B shows an example inwhich the spacer 21, adhering member 22, or spacer 70 that supports thefirst polarizing member 10 employed in the present invention is formedlike a frame having three edges on the liquid crystal cell 54. Moreover,FIG. 14C shows an example in which the spacer 21, adhering member 22, orspacer 70 that supports the first polarizing member 10 employed in thepresent invention is formed like a frame having two adjoining edges.

If the height of the unevenness of the light control member 120 isnearly uniform over the entire surface thereof, along whichever of theedges of the liquid crystal cell the spacer 70 is formed, no problemoccurs. However, if the height of the unevenness of the light controlmember 120 is not uniform, for example, if the height of the unevennessincreases as it recedes farther from the light source 122, the spacer21, adhering member 22, or spacer 70 must be formed at least along theedge of the liquid crystal cell opposite to the edge thereof in contactwith the light source 122. This is intended to prevent the unevenness ofthe light control member 120 from coming into contact with the firstpolarizing member 10, that is, to prevent the spacing between theunevenness of the light control member 120 and the first polarizingmember 10 from being nullified.

FIG. 15A shows an example in which the spacer 21, adhering member 22, orspacer 70 that supports the first polarizing member employed in thepresent invention is formed on the edge of the liquid crystal cell 54opposite to the edge thereof in contact with the light source 122. FIG.15B is a sectional view of the liquid crystal cell shown in FIG. 15A,thus showing the structure of a liquid crystal display device 1F. Thespacer 21, adhering member 22, or spacer 70 is formed outside a displayfield 74. The liquid crystal display device 1F has a liquid crystallayer 26 sealed with a sealing member 24 between a first transparentsubstrate 16 and a second transparent substrate 19. A first polarizingmember 10 composed of a first sheet polarizer 12 and a phase differenceplate 14 is supported by the adhering member 22 and placed on theexternal side of the first transparent substrate 16. A second sheetpolarizer 108 is layered on the external side of the second transparentsubstrate 19, and a reflective layer 27 is formed on the external sideof the second polarizer 108. A transparent electrode and an alignmentlayer are formed on each of the sides of the first and secondtransparent substrates 16 and 19 that are opposed to each other with theliquid crystal layer between them, though they are not shown in FIG.15B. A light source 122 is mounted on one lateral sides of the first andsecond transparent substrates 16 and 19 respectively, and realized withLEDs or a fluorescent tube.

FIG. 16A to FIG. 16E show steps constituting an example of a method ofmanufacturing the first transparent substrate 16 by forming a lightcontrol member 120 on the first transparent substrate 16 that isprovided with an electrode 6 and that is included in a display device inaccordance with the present invention.

FIG. 16A shows a state in which an appropriate quantity of anoptical-setting resin 52 is dropped into a mould 50. The mould 50 hasV-shaped grooves 51, which realize the unevenness of the light controlmember 120, formed in the bottom thereof. The V-shaped grooves 51 areequidistantly and continuously formed in the bottom of the mould 50. Thecontinuous triangular cross-sectional shape of the V-shaped grooves 51may be any of a right angled triangle, an isosceles triangle, and ascalene triangle. Moreover, the optical-setting resin 52 may be, forexample, an acrylic ultraviolet-setting adhesive resin.

Concurrently with, or prior to, the step of dropping an appropriatequantity of the optical-setting resin 52 into the mould 50, theelectrode 6 or an alignment layer formed on the electrode 6 is layeredon the first transparent substrate 16. Herein, a case of the electrode 6alone is layered on the first transparent substrate 16 is explained. Thefirst transparent substrate 16 having the electrode 6 layered thereonis, as shown in FIG. 16B, inserted into the mould 50 so that the firsttransparent substrate 16 will be opposed to the mould 50, and thenpressed. At this time, the resin 52 in the mould 50 is pressed by thefirst transparent substrate 16, and spread all over the mould 50 toenter all the grooves 51. The quantity of the resin 52 is preferablyequal to the total volume of the grooves 51 in the mould 50. However, asthe grooves 51 must be completely filled with the resin 52, the quantityof the resin 52 is normally larger than the total volume of the grooves51. An escape groove (not shown) into which the resin 52 can escape isformed in the mould 50, whereby an extra resin 52 leaking out of thegrooves 51 is removed.

FIG. 16C shows a state in which the grooves 51 in the mould 50 arecompletely filled with the resin 52 while being in contact with thefirst transparent substrate 16. In this example, in this state, a lightsource 58 that lies outside the mould 50 and generates ultraviolet lightirradiates ultraviolet light to the first transparent substrate 16through the electrode 6. At this time, the first transparent substrate16 as well as the electrode 6 is transparent to ultraviolet light.Consequently, the ultraviolet light is transmitted by the electrode 6and first transparent substrate 16 and irradiated to the resin 52.Consequently, the resin 52 sets with the ultraviolet light whileadhering to the first transparent substrate 16.

As mentioned above, after the resin 52 sets while adhering to the firsttransparent substrate 16, the first transparent substrate 16 is, asshown in FIG. 16D, peeled off from the mould 50. Consequently, the resin52 is transferred as the light control member 120 to the firsttransparent substrate 16. FIG. 16E shows the first transparent substrate16 having the light control member 120 thus formed thereon.

The first transparent substrate 16 formed according to the manufacturingmethod shown in FIG. 16A to FIG. 16E may be adapted to a reflectiveliquid crystal cell having a reflective layer formed as an outermostlayer of the liquid crystal cell or may be adapted to a liquid crystalcell having a reflective layer interposed between the first transparentsubstrate 16 and second transparent substrate 19.

FIG. 17A shows the structure of a liquid crystal display device 2A inaccordance with a first embodiment that is manufactured using a firsttransparent substrate 16 having a light control member 120 formedthereon according to the manufacturing method shown in FIG. 16A to FIG.16E, and that includes a reflective layer 27 in a liquid crystal cellthereof. A second transparent substrate 19 is superposed on the side ofthe first transparent substrate 16 where an electrode (not shown) isprovided, with a liquid crystal layer 26 and the reflective layer 27between them, whereby a liquid crystal cell is produced. The liquidcrystal layer 26 is sealed with a sealing member 24 and has a thicknessof about 5 μm. In the present embodiment, the second transparentsubstrate 19 is thinner than the first transparent substrate 16. Thethickness of the second transparent substrate 19 may be level with thatof the first transparent substrate 16 as it is in the aforesaid examplesof liquid crystal cells. Otherwise, the second transparent substrate 19may be thicker than the first transparent substrate 16.

Similarly to the liquid crystal display device 1A shown in FIG. 4A, afirst polarizing member 10 composed of a first polarizer 12 and a phasedifference plate 14 is placed on the external side of the firsttransparent substrate 16 of the liquid crystal display device 2A whilebeing supported by a spacer 21. A light control member 120 formedaccording to the aforesaid manufacturing method is located in a space 3between the first polarizing member 10 and the first transparentsubstrate 16.

A light source 122 is mounted on a lateral side of the first transparentsubstrate 16 with a second polarizer 32 and a second phase differenceplate 34 between them. The upper side in this drawing of the liquidcrystal display device 2A in accordance with the first embodiment is aviewer side. The first transparent substrate 16 is extended to thelateral side of the liquid crystal display device opposite to thelateral side thereof on which the light source 122 is mounted, and islonger than the second transparent substrate 19. An integrated circuit36 for driving the liquid crystal display device 2A is coupled to thebottom of the extended portion via an anisotropic conductive film 38that contains conductive particles 40.

FIG. 17B shows a liquid crystal display device 2B in accordance with asecond embodiment that is manufactured using a first transparentsubstrate 16 or a component having a light control member 120 formedthereon according to the manufacturing method shown in FIG. 16A to FIG.16E, and that includes a reflective layer 27 in a liquid crystal cellthereof. A second transparent substrate 19 is superposed on the side ofthe first transparent substrate 16 where an electrode (not shown) isprovided, with a liquid crystal layer 26 and the reflective layer 27between them, whereby the liquid crystal cell is produced. The liquidcrystal layer 26 is sealed with a sealing member 24 and has a thicknessof about 5 μm.

A difference of the liquid crystal display device 2B from the liquidcrystal display device 2A lies in the shape of the light control member120. In the liquid crystal display device 2A, the continuous triangularcross-sectional shape of the light control member 120 is the samebetween one portion of the light control member 120 located near thelight source 122 and the other portion thereof located near theintegrated circuit 36. On the other hand, in the liquid crystal displaydevice 2B, the continuous triangular cross-sectional shape of oneportion of the light control member 120 located near a light source 122is smaller, and the continuous triangular cross-sectional shape of theother portion thereof located near an integrated circuit 36 is larger.In other words, the height of the continuous triangular cross-sectionalshape of the portion of the light control member 120 located near theintegrated circuit 36 is larger than the height of the continuoustriangular cross-sectional shape of the other portion thereof locatednear the light source 122. The function of the light control member 120having the cross-sectional shape is to equalize the luminance, on thedisplay surface of the liquid crystal cell, generated by light radiatedfrom the light source 122.

The light control member 120 shaped as shown in FIG. 17B can be easilyproduced merely by engraving the shape in the bottom of the mould 50shown in FIG. 16B in advance. The continuous triangular cross-sectionalshape of the light control member 120 shown in FIG. 17B is high all overthe surface of the light control member 120. Depending on a requiredoptical characteristic, the triangular cross-sectional shape may bepartly high or may be made gradually higher. The height of thetriangular cross-sectional shape may be not only varied linearly butalso varied as if to plot a graph of a square function at a certaincurvature.

FIG. 17C shows the structure of a liquid crystal display device 2C inaccordance with a third embodiment that is manufactured using a firsttransparent substrate 16 or a component having a light control member120 formed thereon according to the manufacturing method shown in FIG.16A to FIG. 16E, and that includes a reflective layer 27 in a liquidcrystal cell thereof. A second transparent substrate 19 is superposed onthe side of the first transparent substrate 16 where an electrode (notshown) is provided, with a liquid crystal layer 26 and the reflectivelayer 27 between them, whereby the liquid crystal cell is produced. Theliquid crystal layer 26 is sealed with a sealing member 24 and has athickness of about 5 μm.

A difference of the liquid crystal display device 2C from the liquidcrystal display device 2A shown in FIG. 17A lies in the disposition ofthe light control member 120 on the first transparent substrate 16. Inthe liquid crystal display device 2A in accordance with the firstembodiment shown in FIG. 17A, the light control member 120 is formedinside a double-faced adhesive 21. On the other hand, in the liquidcrystal display device 2C in accordance with the third embodiment shownin FIG. 17C, the light control member 120 is extended to a portion ofthe first transparent substrate to which a spacer 21 is bonded.

FIG. 17D shows the structure of a liquid crystal display device 2D inaccordance with a fourth embodiment that is manufactured using a firsttransparent substrate 16 or a component having a light control member120 formed thereon according to the manufacturing method shown in FIG.16A to FIG. 16E, and that includes a reflective layer 27 in a liquidcrystal cell. A second transparent substrate 19 is superposed on theside of the first transparent substrate 16 where an electrode (notshown) is provided, with a liquid crystal layer 26 and the reflectivelayer 27 between them, whereby the liquid crystal cell is produced. Theliquid crystal layer 26 is sea-led with a sealing member 24 and has athickness of about 5 μm.

A difference of the liquid crystal display device 2D shown in FIG. 17Dfrom the liquid crystal display device 2C shown in FIG. 17C lies in aposition at which the light control member 120 is formed. In the liquidcrystal display device 2D shown in FIG. 17D, the light control member120 is extended to the portion of the first transparent substrate 16having the integrated circuit 36.

As mentioned above, the first transparent substrate 16 is manufacturedwith the light control member 120 formed on the side on which theelectrode 6, that is a component of a display device, is not formed,opposite to the side on which the electrode 6 is formed, according tothe manufacturing method shown in FIG. 16A to FIG. 16E. The firsttransparent substrate 16 can be used to produce a reflective liquidcrystal cell having the reflective layer 26 interposed between the firsttransparent substrate 16 and the second transparent substrate 19 asshown in FIG. 17A to FIG. 17D. Moreover, the first transparent substrate16 can be used to produce a liquid crystal cell having the reflectivelayer 27 formed on the external side of the second transparent substrate19 as shown in FIG. 4A to FIG. 6B.

Moreover, the light control member 120 produced according to themanufacturing method shown in FIG. 7A to FIG. 7E or FIG. 16A to FIG. 16Ecan be adapted to a conventional scattering type liquid crystal displaydevice like the one shown in FIG. 1B.

Furthermore, a twisted nematic (TN) liquid crystal, a super-twistednematic (STN) liquid crystal, or a liquid crystal to be driven accordingto an active matrix addressing method using thin film transistors (TFTs)or thin film diodes (TFDs) may be adopted as the liquid crystal employedin the foregoing embodiments. Liquid crystal display devices formonochromatic display have been described so far. The present inventioncan be effectively applied to a reflective color liquid crystal displaydevice employing a color filter.

Assuming that a color liquid crystal display device employing a colorfilter is manufactured using a first transparent substrate 16 having alight control member 120 formed thereon according to the manufacturingmethod shown in FIG. 16A to FIG. 16E, an electrode, an alignment layer,a liquid crystal, an alignment layer, an electrode, a color filter, alight shade film for shading light from the border of the color filter,and a second transparent substrate 19 are superposed in that order onthe side of the first transparent substrate 16 opposite to the sidethereof having the light control member 120 formed thereon. A lightsource is then mounted on one lateral side of the assembled liquidcrystal cell.

1-12. (canceled)
 13. A method of manufacturing a display device thatcomprises a first transparent substrate having an electrode, a secondtransparent substrate having an electrode, a display cell having anelectro-optic converting member, of which optical characteristic isvaried with an electric action, sealed between said first and secondtransparent substrates, and a light control member made of anultraviolet-setting resin and formed directly on the external side ofsaid first transparent substrate opposite to the side thereof in contactwith said electro-optic converting member, said display devicemanufacturing method comprising the steps of: producing a display cellthat can transmit ultraviolet light; pouring an ultraviolet-settingresin in a mould engraved with line in the shape of a light controlmember; and placing said display cell on said ultraviolet-setting resinin said mould so that said display cell will be superposed on saidultraviolet-setting resin, irradiating ultraviolet light to the side ofsaid display cell opposite to the side thereof in contact with saidultraviolet-setting resin, allowing said ultraviolet-setting resin toset with the ultraviolet light transmitted by said display cell, andremoving said display cell from said mould so as to thus form said lightcontrol member on said display cell.
 14. (canceled)
 15. A display devicemanufacturing method according to claim 13, wherein said display cellplaced in said mould is a single display cell.
 16. A display devicemanufacturing method according to claim 13, wherein said display cellplaced in said mould is a set of display cells including a plurality ofdisplay cells.
 17. A display device manufacturing method according toclaim 16, further comprising a step of cutting said set of display cellsapart so as to produce a single display cell.
 18. A method ofmanufacturing a display device that comprises a first transparentsubstrate having an electrode, a second transparent substrate having anelectrode, a display cell having an electro-optic converting member, ofwhich optical characteristic is varied with an electric action, sealedbetween said first and second transparent substrates, and a lightcontrol member made of an ultraviolet-setting resin and formed directlyon the external side of said first transparent substrate opposite to theside thereof in contact with said electro-optic converting member, saiddisplay device manufacturing method comprising the steps of: forming atleast an electrode on a first transparent substrate; pouring anultraviolet-setting resin in a mould engraved with a line in the shapeof a light control member; placing said first transparent substrate, onwhich said electrode is formed, on said ultraviolet-setting resin insaid mould so that said first transparent substrate will be superposedon said ultraviolet-setting resin; irradiating ultraviolet light to theside of said first transparent substrate opposite to the side thereof incontact with said ultraviolet-setting resin, allowing saidultraviolet-setting resin to set with the ultraviolet light transmittedby said first transparent substrate, and removing said first transparentsubstrate from said mould so as to thus form said light control memberon said first transparent substrate; and bonding said first transparentsubstrate to a second transparent substrate so that said electro-opticconverting member is sandwiched between said first and secondtransparent substrates.
 19. A display device manufacturing methodaccording to claim 18, wherein said electrode formed on said firsttransparent substrate is coated with an alignment layer.
 20. A displaydevice manufacturing method according to claim 18, wherein said firsttransparent substrate having said electrode formed thereon and beingplaced in said mould is a single first transparent substrate.
 21. Adisplay device manufacturing method according to claim 18, wherein saidfirst transparent substrate having said electrode formed thereon andbeing placed in said mould is a set of first transparent substratesincluding a plurality of first transparent substrates.
 22. A displaydevice manufacturing method according to claim 21, further comprising astep of cutting said set of first transparent substrates apart so as toproduce a single first transparent substrate.